Determinants of Secretion and Intracellular Localization of Human Herpesvirus 8 Interleukin-6

Human herpesvirus 8 (HHV-8) interleukin-6 (vIL-6) is distinct from human and other cellular IL-6 proteins in that it does not require the nonsignaling α-receptor subunit for the formation of gp130-based signal transducing complexes and also is largely retained intracellularly rather than being secreted. We and others have reported that vIL-6 is retained and is active in the endoplasmic reticulum (ER) compartment, and data from our laboratory have demonstrated that intracellular vIL-6 is functional in the autocrine promotion of proliferation and survival of HHV-8 latently infected primary effusion lymphoma cells. It has also been reported that vIL-6 secretion in gp130-deficient cells can be enhanced by introduced gp130, thereby implicating the signal transducer in vIL-6 trafficking to the cell surface. We examine here the requirements for intracellular retention and localization of vIL-6. Using vIL-6-hIL-6 chimeric and point-mutated vIL-6 proteins, we identified regions and residues of vIL-6 influencing vIL-6 secretion. However, there was no correlation between vIL-6 secretion and gp130 interaction. We found that vIL-6, but not hIL-6, could associate stably with ER-resident chaperone protein calnexin. Glycosylation-dependent interaction of vIL-6 with calnexin correlated with proper protein folding, but there was no direct relationship between vIL-6-calnexin interaction and intracellular retention. While calnexin depletion had little influence on absolute amounts of secreted vIL-6, it led to markedly reduced levels of intracellular cytokine. This was reversed by gp130 transduction, which had no detectable effect on vIL-6 secretion, but redistributed vIL-6 into ER-distinct locations in calnexin-depleted cells, specifically. Our data reveal that calnexin plays a role in ER localization of vIL-6 and that gp130 promotes ER exit, but not secretion, of the viral cytokine.The viral homologue of interleukin-6, vIL-6, specified by human herpesvirus 8 (HHV-8) shows only 25% amino acid identity to human IL-6 (hIL-6) but is highly related structurally (2, 5). Despite the high degree of conservation of three-dimensional structure and equivalence of receptor interaction interfaces (1, 6), the viral cytokine can associate functionally with the gp130 signal transducer in the absence of the gp80 α-subunit, absolutely required for cellular IL-6 signaling through gp130. The nonsignaling gp80 subunit can be incorporated into vIL-6-induced signaling complexes and indeed seems to have a stabilizing effect that enhances signal transduction (1, 3, 11). Another major difference between vIL-6 and cellular IL-6 proteins, including hIL-6, is that the viral cytokine is very inefficiently secreted, retained largely within the endoplasmic reticulum (ER) compartment, where it is able to transduce signal via gp80-deficient vIL-6₂/gp130₂ tetrameric complexes, exclusively (4, 15). Thus, the unique ability of vIL-6 to signal intracellularly may be explained by its gp80 independence; hIL-6 cannot signal in the ER even when targeted to this compartment (4). The biological significance of intracellular, strictly autocrine signaling by vIL-6 was demonstrated recently in primary effusion lymphoma (PEL) cells, which are latently infected with HHV-8; these cells grew with markedly reduced kinetics and displayed higher rates of apoptosis upon shRNA-mediated vIL-6 depletion relative to cocultured untransduced cells (4). Thus, vIL-6 appears not only to be expressed in latently infected PEL cultures but also to be biologically active in this setting via intracrine signaling.Despite these findings and other mechanistic studies of vIL-6, the means by which the viral cytokine is retained in the ER and secreted so inefficiently is unknown. The elegant work of Meads and Medveczky (15) demonstrated the slow secretion kinetics of vIL-6 relative to hIL-6 and implicated gp130 as a necessary cofactor for vIL-6 secretion. Thus, vIL-6 expressed in gp130-negative Ba/F3 cells was able to be secreted only if gp130 was supplied via expression vector transduction. However, most cell types express gp130; thus, while the signal transducer may be involved in vIL-6 trafficking, the underlying explanation for the very slow rate of vIL-6 secretion must involve other factors.We report here investigations of the structural requirements for vIL-6 intracellular retention, the influence of gp130 on this process, and the possible involvement of ER-resident chaperon proteins for retention of vIL-6 in the ER. Our data identify effects of structural alterations and point mutations of vIL-6 on secretion efficiency, the lack of gp130 involvement in these observed effects, mechanistically relevant interactions of calnexin with the viral cytokine, and the influence of gp130 on vIL-6 subcellular localization and stability in the context of calnexin depletion. The results presented thus further advance our understanding of vIL-6-cellular protein interactions that impact upon its intracellular function.